Circuit substrate and semiconductor device

ABSTRACT

A circuit substrate for improving the reliability and productivity of a semiconductor device, and that semiconductor device. In a circuit substrate to which a semiconductor element is to be flip-chip mounted, at least one island-shaped electrically conductive layer is selectively disposed together with a wiring layer at an element mounting area where the semiconductor element is to be mounted, and an insulating resin layer is disposed over the island-shaped electrically conductive layer. The semiconductor element is secured at the element mounting area to the circuit substrate by an adhesion material to make a semiconductor device. With this, delaminating of the wiring layer inside the semiconductor device is suppressed, and the damage of an electrode is suppressed. The circuit substrate has high reliability and the semiconductor device, having the circuit substrate, is implemented.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefits of priority fromthe prior Japanese Patent Application No. 2006-222825, filed on Aug. 18,2006, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to circuit substrates and semiconductordevices, and particularly to a circuit substrate to which asemiconductor element is to be flip-chip connected in a face-downstructure and a semiconductor device in which the semiconductor elementis flip-chip connected in the face-down structure to the circuitsubstrate.

2. Description of the Related Art

When a semiconductor element is mounted to a circuit substrate to make asemiconductor device, the semiconductor element may be flip-chip mountedto the circuit substrate in a face-down configuration, in which a mainsurface of the semiconductor element faces the circuit substrate, as onesemiconductor-element mounting structure.

To implement this structure, a method (disclosed, for example, inJapanese Unexamined Patent Application Publication No. 9-97816) is usedin which a load is applied to the semiconductor element, having bumps,toward the circuit substrate, having mounting pads, with an adhesivedisposed therebetween to align the bumps with the mounting pads to makethe bumps into contact with the mounting pads; and the adhesive is curedby heat while the bumps and mounting pads are contacting, to secure thesemiconductor element to the circuit substrate to make the semiconductordevice.

In the semiconductor device, manufactured by this method, thesemiconductor element is secured to the circuit substrate with theadhesive supplied therebetween, and a state is maintained in which thebumps of the semiconductor element is pressed against the mounting padsof the circuit substrate. As a result, the mechanical contacts of thebumps and mounting pads are maintained, and their electrical contactsare also obtained and maintained.

In some cases, solid patterns are disposed in addition to wiringpatterns and the mounting pads at an area (hereinafter called an elementmounting area) where the semiconductor element is mounted to the circuitsubstrate (for example, see Japanese Unexamined Patent ApplicationPublication No. 2003-338666).

It has been disclosed that placing such solid patterns increases therigidity of the circuit substrate and improves the reliability of thesemiconductor device; and in addition, plating the surfaces of the solidpatterns with nickel (Ni) and gold (Au) increases the rigidity of thesolid patterns, thus further improving the rigidity of the circuitsubstrate.

It has been also proposed that wiring patterns and dummy patterns aredisposed at the element mounting area in the circuit substrate toeliminate non-uniformity of the density of patterns to prevent warpingof the circuit substrate caused by a difference in thermal expansioncoefficients (for example, in Japanese Unexamined Patent ApplicationPublication No. 2006-32872).

In the above-described related-art cases, the wiring patterns and dummypatterns are plated with gold (Au) to increase corrosion resistance.However, since a gold (Au) plating layer has low contact performancewith adhesives, a sufficient contact force is not obtained. Therefore,it is difficult to maintain the contacts between wiring patterns andconnection terminals of the semiconductor element. To solve thisproblem, in the related-art cases, the dummy patterns have branch shapesto form small protrusions, that is, a plurality of indentations andprojections, to increase the contact force by an anchor effect.

As described above, generally, a low contact force is provided betweenmetals such as gold (Au) and adhesives. Therefore, delaminating islikely to occur at the interface between an adhesive and the gold (Au)plating layers disposed over the surfaces of the dummy patterns andsolid patterns, after mounting.

As a result, it is difficult to maintain a state in which the bumps ofthe semiconductor element is pressed against the mounting pads of thecircuit substrate, and satisfactory electrical connections are notmaintained therebetween. Especially when the semiconductor device isleft in an environment of a high temperature and a high humidity,delaminating further advances and desired reliability is not obtained.

One method can be considered in which insulating resin layers, whichhave high contact performance with adhesives, are disposed over thedummy patterns (solid patterns). When the dummy patterns (solidpatterns) have a large area at the element mounting area, the insulatingresin layers also have a large area.

Having a large area, the insulating resin layers have a large elasticrecovery force. Therefore, when the semiconductor element is mounted tothe circuit substrate, if there are insulating resin layers having alarge area at the element mounting area, the elastic recovery force ofthe insulating resin layers exceeds a bonding load even if the bondingload is applied to the semiconductor element, making the connectionsbetween the bumps of the semiconductor element and the mounting pads ofthe circuit substrate unstable.

If an increased load is applied to the semiconductor element to make thebonding process reliable, internal wiring or circuit elements atportions where the bumps are formed in the semiconductor element may bedamaged.

SUMMARY OF THE INVENTION

In view of the foregoing, it is an object of the present invention toprovide the structure of a circuit substrate having high reliability anda semiconductor device that includes the circuit substrate, to preventdelaminating between electrodes and damage in a semiconductor element.

To accomplish the above object, according to the present invention,there is provided a circuit substrate to which a semiconductor elementis mounted. The circuit substrate includes a. wiring layer disposed atan area opposite the semiconductor element in a surface of the circuitsubstrate, an electrically conductive layer disposed apart from thewiring layer at the area opposite the semiconductor element in thesurface of the circuit substrate, and a resin layer disposed over theelectrically conductive layer.

To accomplish the above object, according to the present invention,there is provided a semiconductor device. The semiconductor deviceincludes a semiconductor element; a circuit substrate to which thesemiconductor element is mounted, including a wiring layer disposed atan area opposite the semiconductor element, an electrically conductivelayer disposed apart from the wiring layer at the area opposite thesemiconductor element, and a resin layer disposed over the electricallyconductive layer; and an adhesion material disposed between the circuitsubstrate and the semiconductor element.

The above and other objects, features and advantages of the presentinvention will become apparent from the following description when takenin conjunction with the accompanying drawings which illustrate preferredembodiments of the present invention by way of example.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a plan of a circuit substrate according to a first embodimentof the present invention. FIG. 1B is a cross-sectional view of a mainpart obtained when a semiconductor element is mounted to the circuitsubstrate.

FIG. 2 is a cross-sectional view of a main part used in a first stage ina process for mounting the semiconductor element to the circuitsubstrate.

FIG. 3 is a cross-sectional view of a main part used in a second stagein the process for mounting the semiconductor element to the circuitsubstrate.

FIG. 4 is a cross-sectional view of a main part used in a third stage inthe process for mounting the semiconductor element to the circuitsubstrate.

FIG. 5 is a cross-sectional view of a main part of a semiconductordevice according to the present invention.

FIG. 6A is a plan of a circuit substrate according to a secondembodiment of the present invention. FIG. 6B is a cross-sectional viewof a main part obtained when a semiconductor element is mounted to thecircuit substrate.

FIG. 7A is a plan of a circuit substrate according to a third embodimentof the present invention. FIG. 7B is a cross-sectional view of a mainpart obtained when a semiconductor element is mounted to the circuitsubstrate.

FIG. 8A is a plan of a circuit substrate according to a fourthembodiment of the present invention. FIG. 8B is a cross-sectional viewof a main part obtained when a semiconductor element is mounted to thecircuit substrate.

FIG. 9A is a plan of a circuit substrate according to a fifth embodimentof the present invention. FIG. 9B is a cross-sectional view of a mainpart obtained when a semiconductor element is mounted to the circuitsubstrate.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be described below in detailby referring to the drawings.

First Embodiment

A circuit substrate and a, form in which a semiconductor element ismounted over the circuit substrate to make a semiconductor device,according to a first embodiment of the present invention will bedescribed.

FIG. 1A shows the structure of a circuit substrate 100 according to thefirst embodiment, and FIG. 1B shows a state in which a semiconductorelement 21 is flip-chip (face-down) mounted over the circuit substrate100 to make a semiconductor device 200. FIG. 1B is a cross-sectionalview corresponding to that taken along line A-A in FIG. 1A.

In FIG. 1A, a rectangular area S enclosed by a dotted line in thecircuit substrate 100 indicates a plane location to be occupied by thesemiconductor element 21 when it is mounted. Hereinafter, therectangular area S is called an element mounting area S.

Over a surface of an insulating base member 10 constituting the circuitsubstrate 100, a plurality of wiring layers 11 is disposed selectivelyat each of the four sides of the element mounting area S.

In the element mounting area S, wide electrode connection sections 12are provided for the plurality of wiring layers 11 in vicinities of theperimeter of the area S. Electrodes of the semiconductor element 21 areconnected to the wide electrode connection sections 12.

To increase the wiring density in the circuit substrate 100, parts 11 aof the wiring layers 11 are extended to vicinities of the center of theelement mounting area S, and are electrically connected to wiring layers(not shown) formed in the rear surface or inside the insulating basemember 10 through vias 13 for interlayer connections. The wiring layers11 a are not necessarily extended or arranged at a constant pitch or auniform density in the element mounting area S.

In the present embodiment, island-shaped electrically conductive layers14 are selectively disposed apart from the wiring layers 11 a in an areahaving a low arrangement density of the wiring layers 11 a. Theisland-shaped electrically conductive layers 14 are generally wider thanthe wiring layers 11 and their shapes are not specified. Theisland-shaped electrically conductive layers 14 are electricallyconnected to a ground potential part of the circuit substrate 100, ifnecessary. The island-shaped electrically conductive layers 14 arecalled dummy patterns in some cases as in the above-describedrelated-art (Japanese Unexamined Patent Application Publication No.2006-32872).

In the present embodiment, insulating resin layers 15 are disposed overthe surfaces of the island-shaped electrically conductive layers 14. Asolder-resist layer 16 is disposed to cover the surface of theinsulating base member 10 and wiring layers 11 b extending toward to theoutside of the element mounting area S, slightly apart from the elementmounting area S at the outside of the element mounting area S.

In the circuit substrate 100, which has the above-described structure,the insulating base member 10 is made from an organic insulating resinsuch as a glass-epoxy resin, a glass-bismaleimide-triazine (glass-BT)resin, or a polyimide. The insulating base member 10 may be made from aninorganic insulating material, such as ceramics or glass.

The insulating base member 10 can have a single-sided wiring structure,a double-sided wiring structure or a multi-layer wiring structuredepending on its use. The circuit substrate 100 is also called a wiringsubstrate or an interposer.

The wiring layers 11, the wide electrode connection sections 12, and theisland-shaped electrically conductive layers 14 are made, for example,from copper (Cu), and their surfaces are plated in two layers withnickel (Ni) and gold (Au) in that order from the lower layer. Thesemetal layers are formed together by a combination of formation over theentire surface of the circuit substrate 100 and selection etching(so-called photolithography) or by a selection plating method to have athickness of 7 to 20 μm.

As described above, the insulating resin layers 15 are disposed over theisland-shaped electrically conductive layers 14 selectively disposed.

The insulating resin layers 15 can be made from the same material asthat constituting the solder-resist layer 16. These layers can be madefrom a developing-type resist material, a thermosetting resist material,or an ultraviolet-curable resist material. More specifically, theselayers can be made from a resin such as an epoxy resin, an acrylicresin, or a polyimide resin, or a mixture of these resins. Theinsulating resin layers 15 and the solder-resist layer 16 may be madefrom different materials.

The insulating resin layers 15 and the solder-resist layer 16 can beselectively disposed by a combination of forming these layers overtarget layers and photolithography processing applied to the targetlayers. The thickness of these layers is about 5 to 30 μm.

FIG. 1B shows the state in which the semiconductor element 21 isflip-chip mounted, with its face down, to the circuit substrate 100,having the above-described structure, to make the semiconductor device200.

In the semiconductor device 200, the semiconductor element 21 is securedto the circuit substrate 100 with an adhesion material (adhesive) 31filling between the semiconductor element 21 and the circuit substrate100. The adhesion material 31 is also called an underfill material.

In the semiconductor element 21, a so-called wafer process is, appliedto one main surface of a semiconductor base member made from silicon(Si), gallium arsenide (GaAs), or the like to form an electronic circuithaving active elements such as transistors, passive elements such ascapacitors, and wiring layers for connecting these elements.

Over the one main surface of the semiconductor base member, where theelectronic circuit is formed, bumps (protruding electrodes) aredisposed, as external-connection electrodes 23, over electrode pads 22connected to the wiring layers. The electrode pads 22 are made from ametal having aluminum (Al) or copper as a main component.

The bumps, serving as the external-connection electrodes 23, are madefrom gold (Au), copper (Cu), an alloy of gold and copper, solder, or thelike, and are formed by a ball bonding method which uses metal wires, aplating method, a printing method, a transfer method, and others.

The adhesion material 31 is a thermosetting adhesive made from an epoxyresin, a polyimide resin, an acrylic resin, or the like and is aninsulator or is anisotropically electrically conductive. Before cured,the adhesion material 31 has either a paste-like shape or a sheet shape.

After adhesion treatment, the adhesion material 31 forms a fillet 32from the side faces of the semiconductor element 21 to the side faces ofthe solder-resist layer 16.

In the semiconductor device 200, which has the above-describedstructure, the wiring layers 11 and the island-shaped electricallyconductive layers 14 are selectively disposed at the element mountingarea S in the circuit substrate 100, as described above.

The selective arrangement of the island-shaped electrically conductivelayers 14 improves non-uniformity of the density of electricallyconductive portions over the circuit substrate 100 and increases therigidity of the circuit substrate 100 to reduce warpage or bow of thecircuit substrate 100.

In the semiconductor device 200, since the insulating resin layers 15are disposed over the surfaces of the island-shaped electricallyconductive layers 14, the adhesion material 31 contacts the insulatingresin layers 15. The island-shaped electrically conductive layers 14 andthe adhesion material 31 are strongly connected through the insulatingresin layers 15, and delaminating does not occur between theisland-shaped electrically conductive layers 14 and the adhesionmaterial 31.

Between the adjacent wiring layers 11 and between the wiring layers 11and the island-shaped electrically conductive layers 14, the surface ofthe insulating base member 10 contacts the adhesion material 31. Whenthe insulating base member 10 is made from an organic material, thecontact performance between the insulating base member 10 and theadhesion material 31 is satisfactory.

Since uneven portions are formed depending on the thickness (height) ofthe wiring layers 11 and the island-shaped electrically conductivelayers 14 between the adjacent wiring layers 11 and between the wiringlayers 11 and the island-shaped electrically conductive layers 14, asthe area where the adhesion material 31 contacts increases, a so-calledanchor effect occurs, preventing delaminating between the wiring layers11 and the adhesion material 31.

As described above, according to the present embodiment, delaminatingdoes not occur at the interfaces of the adhesion material 31, and thewiring layers 11 and the island-shaped electrically conductive layers14; and satisfactory mechanical contacts and satisfactory electricalcontacts can be maintained between the electrode connection sections 12of the circuit substrate 100 and the external-connection electrodes 23of the semiconductor element 21.

The insulating resin layers 15 are selectively disposed only over theisland-shaped electrically conductive layers 14.

Therefore, the area occupied by the insulating resin layers 15 in theelement mounting area S is substantially small, and the elastic recoveryforce of the insulating resin layers 15, which is generated when thesemiconductor element 21 is mounted to the circuit substrate 100, issmall.

Consequently, a load applied to the semiconductor element 21 exceeds theelastic recovery force of the insulating resin layers 15 even if theload is not made large, and the electrode connection sections 12 of thecircuit substrate 100 and the external-connection electrodes 23 of thesemiconductor element 21 can be connected in a stable state.

Since the load applied to the semiconductor element 21 does not need tobe made large, internal wirings or functional elements at portions wherethe external-connection electrodes 23 of the semiconductor element 21are disposed are not damaged.

Therefore, even when the semiconductor element 21 is pressed against thecircuit substrate 100 through the thermosetting adhesion material 31with the load and heat supplied, the internal wirings or internalelements of the semiconductor element 21 are not damaged, and theelectrode connection sections 12 of the circuit substrate 100 and theexternal-connection electrodes 23 of the semiconductor element 21 arereliably connected. In other words, the semiconductor device 200 hashigh reliability.

Next, a semiconductor-device manufacturing method that includes aprocess for mounting the semiconductor element 21 to the circuitsubstrate 100 will be described with reference to FIG. 2 to FIG. 5.

FIG. 2 shows a state where the semiconductor element 21 is placed overthe circuit substrate 100.

As described above, the semiconductor element 21 is flip-chip mounted,with its face down, to the circuit substrate 100.

Before the semiconductor element 21 is mounted, the paste-like orsheet-shaped adhesion material 31 is supplied and disposed in theelement mounting area S of the circuit substrate 100. A dispensermethod, a printing method, or a pasting method can be used as thesupplying method.

A plurality of electrode pads (electrode lands) 17 to whichexternal-connection terminals of the circuit substrate 100 are to bedisposed is disposed over the other main surface of the circuitsubstrate 100, which is the surface opposite the surface to which thesemiconductor element 21 is mounted.

Around the plurality of electrode pads 17, wiring layers 11 c aredisposed, if necessary. The wiring layers 11 c are covered by asolder-resist layer 16.

The wiring layers, electrode pads, and others disposed over both mainsurfaces of the circuit substrate 100 are selectively connected throughwiring layers and interlayer connection sections formed inside thecircuit substrate 100.

Since the other components of the circuit substrate 100 have beendescribed by referring to FIG. 1B, a description thereof is omittedhere.

The semiconductor element 21, where the external-connection electrodes23 have been disposed at the electrode pads 22, is suctioned and held bya bonding tool 70 heated in advance. The heating temperature is set toabout 150° C. to 250° C.

The circuit substrate 100 is suctioned and held over a bonding stage(not shown), and if necessary, the circuit substrate 100 and theadhesion material 31 are preparatorily heated. The heating temperatureis set to about 50° C. to 100° C.

The semiconductor element 21 is placed to face the circuit substrate100; the external-connection electrodes 23 of the semiconductor element21 are positioned correspondingly to the electrode connection sections12 of the circuit substrate 100; and the semiconductor element 21 islowered toward the circuit substrate 100 in a direction indicated byarrows.

The semiconductor element 21 is lowered to the circuit substrate 100 tomake the external-connection electrodes 23 of the semiconductor element21 contact with the electrode connection sections 12 of the circuitsubstrate 100.

The bonding tool 70 applies pressure to the semiconductor element 21 toapply a load to the external-connection electrodes 23 of thesemiconductor element 21, which has contacted the electrode connectionsections 12 of the circuit substrate 100. The load is set, for example,to 5 to 50 gf/bump.

With the applied load, the adhesion material 31 flows outward, that is,toward the outside of the element mounting area S, between thesemiconductor element 21 and the circuit substrate 100, and is cured byheat (at about 150° C. to 250° C.).

When the adhesion material 31 flows as described above, thesolder-resist layer 16 serves as a dam for blocking unnecessary flow ofthe adhesion material 31. With this, the adhesion material 31 forms thefillet 32, which is stable.

FIG. 3 shows the above-described state.

Then, the suction of the bonding tool 70 is released to separate thesemiconductor element 21 from the bonding tool 70, and the bonding tool70 is raised (not shown).

The circuit substrate 100 and the semiconductor element 21, which hasbeen mounted and secure thereto, are subjected to heat treatment in anoven. The adhesion material 31 is completely cured and mounting thesemiconductor element 21 to the circuit substrate 100 is finished.

FIG. 4 shows the above-described state.

In this treatment, the heating temperature is set, for example, to 120°C. to 180° C., and the heating time is set, for example, to about 30 to90 minutes.

In the process shown in FIG. 3, when the adhesion material 31 is cured,for example, at a curing rate of about 80%, the process shown in FIG. 4can be omitted.

Then, solder balls serving as external-connection terminals 18 areformed over the electrode pads 17 disposed over the rear surface of thecircuit substrate 100 by a reflow method to make the semiconductordevice 200 having a ball-grid-array (BGA) package structure.

FIG. 5 shows the above-described state.

The arrangement of the solder balls may be omitted to make thesemiconductor device 200 have a land-grid-array (LGA) package structure,which has the electrode pads 17 as external-connection terminals. Theshape of the external-connection terminals may be another shape such asa lead shape or a pin shape.

The positions where the external-connection terminals 18 are disposedare not limited to those over the main surface-of the circuit substrate100, opposite the surface where the semiconductor element 21 is mounted.The external-connection terminals 18 may be disposed over the mainsurface where the semiconductor element 21 is mounted or over a sideface of the circuit substrate 100, if necessary.

A second embodiment of the present invention will be described next.

Second Embodiment

A circuit substrate and a form in which a semiconductor element ismounted over the circuit substrate to make a semiconductor device,according to a second embodiment of the present invention will bedescribed.

FIG. 6A shows the structure of a circuit substrate 101 according to thesecond embodiment, and FIG. 6B shows a state in which a semiconductorelement 21 is flip-chip (face-down) mounted over the circuit substrate101 to make a semiconductor device 201. FIG. 6B is a cross-sectionalview corresponding to that taken along line A-A in FIG. 6A.

In the semiconductor device 201 according to the second embodiment,exposure sections 14a are provided in island-shaped electricallyconductive layers 14 selectively disposed over an insulating base member10 of the circuit substrate 101 so as to expose upper edge surfaces ofthe island-shaped electrically conductive layers 14. Insulating resinlayers 15 are selectively disposed over the other sections of theisland-shaped electrically conductive layers 14.

The insulating resin layers 15 have smaller areas than the island-shapedelectrically conductive layers 14. The exposure sections 14 a have awidth about the same as that of wiring layers 11.

The second embodiment has the same structure as the first embodimentexcept for how the insulating resin layers 15 are disposed over theisland-shaped electrically conductive layers 14, and therefore, adetailed description of the same structure is omitted.

In the semiconductor device 201, which has the above-describedstructure, the wiring layers 11 and the island-shaped electricallyconductive layers 14 are selectively disposed at an element mountingarea S in the circuit substrate 101.

The selective arrangement of the island-shaped electrically conductivelayers 14 improves non-uniformity of the density of electricallyconductive portions over the circuit substrate 101 and increases therigidity of the circuit substrate 101 to reduce warpage or bow of thecircuit substrate 101.

In the semiconductor device 201, since the insulating resin layers 15are disposed over surfaces of the island-shaped electrically conductivelayers 14, an adhesion material 31 contacts the insulating resin layers15. The island-shaped electrically conductive layers 14 and the adhesionmaterial 31 are strongly connected through the insulating resin layers15, and delaminating does not occur between the island-shapedelectrically conductive layers 14 and the adhesion material 31.

Since the insulating resin layers 15 are selectively disposed partiallyover the island-shaped electrically conductive layers 14 with smallerareas than the island-shaped electrically conductive layers 14 in thesemiconductor device 201, steps are formed between the island-shapedelectrically conductive layers 14 and the insulating resin layers 15.

Therefore, when the adhesion material 31 is placed over the insulatingbase member 10 including the insulating resin layers 15, the contactperformance of the adhesion material 31 and the insulating resin layers15 is further improved due to an increase in the contact area caused bythe steps.

Since the area of the insulating resin layers 15 disposed partially overthe island-shaped electrically conductive layers 14 are restricted inthe above-described structure, the elastic recovery force of theinsulating resin layers 15 is suppressed to a lower level when thesemiconductor element 21 is mounted to the circuit substrate 101.

Consequently, a load applied to the semiconductor element 21 exceeds theelastic recovery force of the insulating resin layers 15 even if theload is not made large, and electrode connection sections 12 of thecircuit substrate 101 and external-connection electrodes 23 of thesemiconductor element 21 can be connected in a stable state.

Since the load applied to the semiconductor element 21 does not need tobe made large, internal wirings or functional elements at portions wherethe external-connection electrodes 23 of the semiconductor element 21are disposed are not damaged.

Therefore, even when the semiconductor element 21 is pressed against thecircuit substrate 101 through the thermosetting adhesion material 31with the load and heat supplied, the internal wirings or internalelements of the semiconductor element 21 are not damaged, and theelectrode connection sections 12 of the circuit substrate 101 and theexternal-connection electrodes 23 of the semiconductor element 21 arereliably connected. In other words, the semiconductor device 201 hashigh reliability.

A third embodiment of the present invention will be described next.

Third Embodiment

A circuit substrate and a form in which a semiconductor element ismounted over the circuit substrate to make a semiconductor device,according to a third embodiment of the present invention will bedescribed.

FIG. 7A shows the structure of a circuit substrate 102 according to thethird embodiment, and FIG. 7B shows a state in which a semiconductorelement 21 is flip-chip (face-down) mounted over the circuit substrate102 to make a semiconductor device 202. FIG. 7B is a cross-sectionalview corresponding to that taken along line A-A in FIG. 7A.

In the semiconductor device 202 according to the third embodiment,insulating resin layers 15 are divided in a grating manner and disposedover island-shaped electrically conductive layers 14 selectivelydisposed over an insulating base member 10 of the circuit substrate 102.In other words, each insulating resin layer 15 is divided into aplurality of pieces and disposed over one island-shaped electricallyconductive layer 14. If an island-shaped electrically conductive layer14 has a small area, it may be not allowed to place a plurality ofpieces of an insulating resin layer 15 thereon.

The third embodiment also has the same structure as the first embodimentexcept for how the insulating resin layers 15 are disposed over theisland-shaped electrically conductive layers 14, and therefore, adetailed description of the same structure is omitted.

In the semiconductor device 202, which has the above-describedstructure, wiring layers 11 and the island-shaped electricallyconductive layers 14 are selectively disposed at an element mountingarea S in the circuit substrate 102.

The selective arrangement of the island-shaped electrically conductivelayers 14 improves non-uniformity of the density of electricallyconductive portions over the circuit substrate 102 and increases therigidity of the circuit substrate 102 to reduce warpage or bow of thecircuit substrate 102.

In the semiconductor device 202, since the insulating resin layers 15are disposed over surfaces of the island-shaped electrically conductivelayers 14, an adhesion material 31 contacts the insulating resin layers15. The island-shaped electrically conductive layers 14 and the adhesionmaterial 31 are strongly connected through the insulating resin layers15, and delaminating does not occur between the island-shapedelectrically conductive layers 14 and the adhesion material 31.

Since each insulating resin layer 15 is divided into a plurality ofpieces and disposed over one island-shaped electrically conductive layer14 in the semiconductor device 202, steps are formed between theplurality of pieces of the resin layer.

Therefore, when the adhesion material 31 is placed over the insulatingbase member 10 including the insulating resin layers 15, the contactperformance of the adhesion material 31 and the insulating resin layers15 is improved due to an increase in the contact area caused by thesteps.

The adhesion material 31 can flow between the plurality of pieces due tothe steps, the contact performance of the adhesion material 31 and theinsulating resin layers 15 is further improved due to the so-calledanchor effect.

The insulating resin layers 15 are divided in the grating manner to forma plurality of steps. The present invention is not limited to this case.The insulating resin layers 15 may be divided in a line and space manneror into portions having any necessary shape. Alternatively, a pluralityof indentations may be formed in parallel in the insulating resin layers15.

The division lines of the insulating resin layers 15 may be stopped atthe middle in the thickness direction of the insulating resin layers 15,not reaching the surfaces of the island-shaped electrically conductivelayers 14.

Since the insulating resin layers 15 are divided into a plurality ofpieces in the above-described structure, the elastic recovery force ofthe insulating resin layers 15 is restricted when the semiconductorelement 21 is mounted to the circuit substrate 102.

Consequently, a load applied to the semiconductor element 21 exceeds theelastic recovery force of the insulating resin layers 15 even if theload is not made large, and electrode connection sections 12 of thecircuit substrate 102 and external-connection electrodes 23 of thesemiconductor element 21 can be connected in a stable state.

Since the load applied to the semiconductor element 21 does not need tobe made large, internal wirings or functional elements at portions wherethe external-connection electrodes 23 of the semiconductor element 21are disposed are not damaged.

Therefore, even when the semiconductor element 21 is pressed against thecircuit substrate 102 through the thermosetting adhesion material 31with the load and heat supplied, the internal wirings or internalelements of the semiconductor element 21 are not damaged, and theelectrode connection sections 12 of the circuit substrate 102 and theexternal-connection electrodes 23 of the semiconductor element 21 arereliably connected. In other words, the semiconductor device 202 hashigh reliability.

A fourth embodiment of the present invention will be described next.

Fourth Embodiment

A circuit substrate and a form in which a semiconductor element ismounted over the circuit substrate to make a semiconductor device,according to a fourth embodiment of the present invention will bedescribed.

FIG. 8A shows the structure of a circuit substrate 103 according to thefourth embodiment, and FIG. 8B shows a state in which a semiconductorelement 21 is flip-chip (face-down) mounted over the circuit substrate103 to make a semiconductor device 203. FIG. 8B is a cross-sectionalview corresponding to that taken along line A-A in FIG. 8A.

In the semiconductor device 203 according to the fourth embodiment,insulating resin layers 15 are disposed over island-shaped electricallyconductive layers 14 selectively disposed over an insulating base member10 of the circuit substrate 103 to cover also the side faces of theisland-shaped electrically conductive layers 14. In other words, eachinsulating resin layer 15 is disposed over one island-shapedelectrically conductive layer 14 to cover the upper face and side facethereof and to reach the insulating base member 10.

The fourth embodiment also has the same structure as the firstembodiment except for how the insulating resin layers 15 are disposedover the island-shaped electrically conductive layers 14, and therefore,a detailed description of the same structure is omitted.

In the semiconductor device 203, which has the above-describedstructure, wiring layers 11 and the island-shaped electricallyconductive layers 14 are selectively disposed at an element mountingarea S in the circuit substrate 103.

The selective arrangement of the island-shaped electrically conductivelayers 14 improves non-uniformity of the density of electricallyconductive portions over the circuit substrate 103 and increases therigidity of the circuit substrate 103 to reduce warpage or bow of thecircuit substrate 103.

In the semiconductor device 203, since the insulating resin layers 15are disposed over the surfaces of the island-shaped electricallyconductive layers 14, an adhesion material 31 contacts the insulatingresin layers 15. The island-shaped electrically conductive layers 14 andthe adhesion material 31 are strongly connected through the insulatingresin layers 15, and delaminating does not occur between theisland-shaped electrically conductive layers 14 and the adhesionmaterial 31.

In the semiconductor device 203, which has the above-describedstructure, the insulating resin layers 15 disposed over theisland-shaped electrically conductive layers 14 also cover the sidefaces thereof and reach the surface of the insulating base member 10.

Therefore, when the adhesion material 31 is placed over the insulatingbase member 10 including the insulating resin layers 15, the contactperformance of the adhesion material 31 and the insulating resin layers15 is further improved due to an increase in the contact area at theside faces of the island-shaped electrically conductive layers 14.

Since the area of the insulating resin layers 15 is not greatlyincreased in the above-described structure, the elastic recovery forceof the insulating resin layers 15 is restricted when the semiconductorelement 21 is mounted to the circuit substrate 103.

Consequently, a load applied to the semiconductor element 21 exceeds theelastic recovery force of the insulating resin layers 15 even if theload is not made large, and electrode connection sections 12 of thecircuit substrate 103 and external-connection electrodes 23 of thesemiconductor element 21 can be connected in a stable state.

Since the load applied to the semiconductor element 21 does not need tobe made large, internal wirings or functional elements at portions wherethe external-connection electrodes 23 of the semiconductor element 21are disposed are not damaged.

Therefore, even when the semiconductor element 21 is pressed against thecircuit substrate 103 through the thermosetting adhesion material 31with the load and heat supplied, the internal wirings or internalelements of the semiconductor element 21 are not damaged, and theelectrode connection sections 12 of the circuit substrate 103 and theexternal-connection electrodes 23 of the semiconductor element 21 arereliably connected. In other words, the semiconductor device 203 hashigh reliability.

A fifth embodiment of the present invention will be described next.

Fifth Embodiment

A circuit substrate and a form in which a semiconductor element ismounted over the circuit substrate to make a semiconductor device,according to a fifth embodiment of the present invention will bedescribed.

FIG. 9A shows the structure of a circuit substrate 104 according to thefifth embodiment, and FIG. 9B shows a state in which a semiconductorelement 21 is flip-chip (face-down) mounted over the circuit substrate104 to make a semiconductor device 204. FIG. 9B is a cross-sectionalview corresponding to that taken along line A-A in FIG. 9A.

In the semiconductor device 204 according to the fifth embodiment,insulating resin layers 15 thinner than in the first embodiment aredisposed over island-shaped electrically conductive layers 14selectively disposed over an insulating base member 10 of the circuitsubstrate 104. In other words, the insulating resin layers 15 aredisposed over the island-shaped electrically conductive layers 14 with arelatively small thickness.

The height from a surface 10 a of the insulating base member 10 to asurface 15 a of the insulating resin layers 15 is made smaller than theheight of a solder-resist layer 16 disposed at the perimeter of anelement mounting area S.

More specifically, the thickness of the insulating resin layers 15 isset to 2 to 10 μm in the present embodiment whereas the thickness is 5to 30 μm in the first to fourth embodiments.

The fifth embodiment also has the same structure as the first embodimentexcept for how the insulating resin layers 15 are disposed over theisland-shaped electrically conductive layers 14, and therefore, adetailed description of the same structure is omitted.

In the semiconductor device 204, which has the above-describedstructure, wiring layers 11 and the island-shaped electricallyconductive layers 14 are selectively disposed at the element mountingarea S in the circuit substrate 104.

The selective arrangement of the island-shaped electrically conductivelayers 14 improves non-uniformity of the density of electricallyconductive portions over the circuit substrate 104 and increases therigidity of the circuit substrate 104 to reduce warpage or bow of thecircuit substrate 104.

In the semiconductor device 204, since the insulating resin layers 15are disposed over the surfaces of the island-shaped electricallyconductive layers 14, an adhesion material 31 contacts the insulatingresin layers 15. The island-shaped electrically conductive layers 14 andthe adhesion material 31 are strongly connected through the insulatingresin layers 15, and delaminating does not occur between theisland-shaped electrically conductive layers 14 and the adhesionmaterial 31.

Since the insulating resin layers 15 are made thinner in theabove-described structure, the elastic recovery force of the insulatingresin layers 15 is restricted to a low level when the semiconductorelement 21 is mounted to the circuit substrate 104.

Consequently, a load applied to the semiconductor element 21 exceeds theelastic recovery force of the insulating resin layers 15 even if theload is not made large, and electrode connection sections 12 of thecircuit substrate 104 and external-connection electrodes 23 of thesemiconductor element 21 can be connected in a stable state.

Since the load applied to the semiconductor element 21 does not need tobe made large, internal wirings or functional elements at portions wherethe external-connection electrodes 23 of the semiconductor element 21are disposed are not damaged.

Therefore, even when the semiconductor element 21 is pressed against thecircuit substrate 104 through the thermosetting adhesion material 31with the load and heat supplied, the internal wirings or internalelements of the semiconductor element 21 are not damaged, and theelectrode connection sections 12 of the circuit substrate 104 and theexternal-connection electrodes 23 of the semiconductor element 21 arereliably connected.

In addition, since the insulating resin layers 15 are made thinner, thespace between the insulating resin layers 15 and the semiconductorelement 21 is extended to increase the flowability of the adhesionmaterial 31. A void is prevented from being produced in the adhesionmaterial 31 or is reduced, and a portion which is not filled with theadhesion material 31 is prevented from being generated or is reduced.

Therefore, the reliability of the semiconductor device 204 is increased.

Comparison with the Related Art

A comparison in advantages between the present invention and the relatedart will be described below.

A semiconductor device A having island-shaped electrically conductivelayers 14 but not having insulating resin layers 15 thereover, accordingto the related art and a semiconductor device B having island-shapedelectrically conductive layers 14 and also having insulating resinlayers 15 thereover, according to the concept of the present inventionwere environmentally evaluated in a moisture/reflow sensitivity test andan autoclave test to compare the reliability of the semiconductordevices.

As a semiconductor element 21 to be mounted to the semiconductor deviceA and the semiconductor device B, a logic integrated-circuit elementhaving dimensions of 6.57 by 6.57 mm, an electrode-pad pitch of 50 μm(minimum pitch), 414 electrode pads, and external-connection terminalsmade from gold (Au) was used.

The circuit substrate having the structure shown in FIG. 1 was usedexcept for the insulating resin layers 15. As the insulating base member10, a four-layer buildup wiring substrate made from glass-BT was used.

The island-shaped electrically conductive layers 14 were set to have theground potential. A paste-like thermosetting insulating epoxy resin wasused as the adhesion material 31.

In the semiconductor device A, insulating resin layers 15 were notdisposed over the island-shaped electrically conductive layers 14, but anickel (Ni) layer first and then a gold (Au) layer were disposed overthe island-shaped electrically conductive layers 14. These metal layerswere formed by the plating method.

In contrast, in the semiconductor device B, the insulating resin layers15 made from the same material as solder resist were disposed over theisland-shaped electrically conductive layers 14, and then, a nickel (Ni)layer first and then a gold (Au) layer were disposed over exposed wiringpatterns, electrode connection sections, and the island-shapedelectrically conductive layers 14.

The semiconductor devices A and B were flip-chip mounted to the circuitsubstrates by an adhesive-intervening-type thermocompression bondingmethod.

In mounting conditions, a load was set to 17 gf/bump, the heatingtemperature of the semiconductor elements was set to 280° C., and theheating temperature of the circuit substrates was set to 70° C. Thebonding time was five seconds.

Ten samples of each of the semiconductor devices A and B having astructure similar to that shown in FIG. 5 were manufactured in theforegoing way and their performance was compared.

The results of the moisture/reflow sensitivity test will be describedfirst.

The ten samples of each of the semiconductor devices A and B were leftin an environment having a temperature of 30° C. and a relative humidityof 80% for 120 hours, and then were applied heating treatment at a peaktemperature of 260° C. in an infrared reflow apparatus.

Then, the ten samples were left in an environment having a temperatureof 30° C. and a relative humidity of 80% for 96 hours, and then weresubjected to heating treatment at a peak temperature of 260° C. in theinfrared reflow apparatus.

The samples were visually inspected at their insides, and were furtherchecked for their electric characteristics.

In the inside visual inspection, whether delamination occurred at theinterface between the adhesion material 31 and the semiconductor element21 and the interfaces between the adhesion material 31, and the basemember 10 of the circuit substrate, the island-shaped electricallyconductive layers 14, wiring patterns 11, and external-connectionelectrodes 23 by using an ultrasonic flaw detector.

In the inside visual inspection, no defects were found in any of the tensamples of each of the semiconductor devices A and B.

In the electric-characteristics check, according to a predetermined testprogram, the samples were electrically operated, and the electricalcharacteristics thereof were measured to check whether predeterminedcharacteristics were obtained.

In the electric-characteristics check, no defects were found in any ofthe ten samples of each of the semiconductor devices A and B.

After the moisture/reflow sensitivity test, the autoclave test wasconducted. The results thereof will be described below. In the autoclavetest, the samples were left in an environment having a temperature of121° C. and a relative humidity of 99.8% for a predetermined period oftime.

Then, the samples were checked for their electric characteristics. If adefect was found in the electric-characteristics check, that sample wasvisually inspected at its inside.

The same methods as those in the moisture/reflow sensitivity test wereused for the electric-characteristic check and inside visual inspectionin this test.

In the electric-characteristic check, no defect was found in the tensamples of the semiconductor device A for up to 504 hours and in the tensamples of the semiconductor device B for up to 840 hours.

Defects were found in five of the ten samples of the semiconductordevice A in 672 hours and two of the ten samples of the semiconductordevice B in 1,008 hours in their electric characteristics.

In the inside visual inspection, delaminating was found in all of thesamples in which defects were found in their electric characteristics,of the semiconductor devices A and B.

Delaminating was found in the interface between the semiconductorelement 21 and the adhesion material 31 in a vicinity of the perimeterof the semiconductor element 21, and the interface with the adhesionmaterial 31 over and in a vicinity of the island-shaped electricallyconductive layers 14, in the samples of the semiconductor device A.

In the samples of the semiconductor device B, delaminating was found inthe interface between the semiconductor element 21 and the adhesionmaterial 31 in a vicinity of an outer corner of the semiconductorelement 21. No delaminating of the adhesion material 31 occurred overthe island-shaped electrically conductive layers 14.

From the above-described environmental evaluation, it was confirmed thatthe semiconductor device B, according to the present invention, hashigher reliability than the semiconductor device A, having aconventional structure.

Any of the first to fifth embodiments of the present invention can beselected and combined.

The present invention is not limited to cases where one of the first tofifth embodiments, described above, is applied to all of a plurality ofisland-shaped electrically conductive layers 14 disposed at an elementmounting area in a circuit substrate. The present invention can beapplied to only island-shaped electrically conductive layers 14 havinglarger areas.

In addition, one of the first to fifth embodiments can be applied to oneof insulating resin layers 15 disposed over a plurality of island-shapedelectrically conductive layers 14.

In a circuit substrate according to the present invention, sinceisland-shaped electrically conductive layers are disposed separately andapart from wiring layers at an element mounting area in the circuitsubstrate, non-uniformity of the density of electrically conductiveportions in the circuit substrate is improved and the rigidity of thecircuit substrate is increased to reduce warpage or bow of the circuitsubstrate.

In a circuit substrate and a semiconductor device according to thepresent invention, since resin layers are disposed over the surfaces ofisland-shaped electrically conductive layers in the circuit substrate,an adhesion material for securing a semiconductor element contacts theresin layers. With this structure, the island-shaped electricallyconductive layers and the adhesion material are strongly connectedthrough the resin layers, and delaminating does not occur between theisland-shaped electrically conductive layers and the adhesion material.

As described above, according to the present embodiment, delaminating ofwiring layers inside a semiconductor device is prevented; and aconnection defect is prevented between electrode connection sections ofa circuit substrate and external-connection electrodes of asemiconductor element. Therefore, a highly reliable circuit substrateand a semiconductor device using the circuit substrate can beimplemented.

The foregoing is considered as illustrative only of the principles ofthe present invention. Further, since numerous modifications and changeswill readily occur to those skilled in the art, it is not desired tolimit the invention to the exact construction and applications shown anddescribed, and accordingly, all suitable modifications and equivalentsmay be regarded as falling within the scope of the invention in theappended claims and their equivalents.

1. A circuit substrate on which a semiconductor element is mounted,comprising: a wiring layer disposed at an area opposite thesemiconductor element on a surface of the circuit substrate; anelectrically conductive layer disposed apart from the wiring layer atthe area opposite the semiconductor element on the surface of thecircuit substrate; and a resin layer disposed over the electricallyconductive layer.
 2. The circuit substrate according to claim 1, whereinthe resin layer is disposed only over the electrically conductive layerat the area opposite the semiconductor element in the surface of thecircuit substrate.
 3. The circuit substrate according to claim 1,wherein the electrically conductive layer is made from copper (Cu), andtwo metal layers of a nickel (Ni) layer and a gold (Au) layer are formedin that order from the lower layer over a surface of the electricallyconductive layer.
 4. The circuit substrate according to claim 1, whereinthe resin layer, disposed over the electrically conductive layer, alsocovers a side face of the electrically conductive layer.
 5. The circuitsubstrate according to claim 1, wherein the resin layer, disposed overthe electrically conductive layer, is divided into a plurality of piecesand disposed.
 6. The circuit substrate according to claim 1, wherein theresin layer, disposed over the electrically conductive layer, is formedto have a smaller area than the electrically conductive layer so as toexpose an upper edge surface of the electrically conductive layer. 7.The circuit substrate according to claim 6, wherein the upper edgesurface exposed has the same width as the wiring layer.
 8. The circuitsubstrate according to claim 1, wherein the height from a surface of abase member constituting the circuit substrate to a surface of the resinlayer is lower than the height of solder resist disposed at a perimeterportion of the area.
 9. A semiconductor device comprising: asemiconductor element; a circuit substrate on which the semiconductorelement is mounted, comprising a wiring layer disposed at an areaopposite the semiconductor element, an electrically conductive layerdisposed apart from the wiring layer at the area opposite thesemiconductor element, and a resin layer disposed over the electricallyconductive layer; and an adhesion material disposed between the circuitsubstrate and the semiconductor element.
 10. The semiconductor deviceaccording to claim 9, wherein the resin layer is disposed only over theelectrically conductive layer at the area opposite the semiconductorelement on a surface of the circuit substrate.
 11. The semiconductordevice according to claim 9, wherein the electrically conductive layeris made from copper (Cu), and two metal layers of a nickel (Ni) layerand a gold (Au) layer are formed in that order from the lower layer overa surface of the electrically conductive layer.
 12. The semiconductordevice according to claim 9, wherein the resin layer, disposed over theelectrically conductive layer, also covers a side face of theelectrically conductive layer.
 13. The semiconductor device according toclaim 9, wherein the resin layer, disposed over the electricallyconductive layer, is divided into a plurality of pieces and disposed.14. The semiconductor device according to claim 9, wherein the resinlayer, disposed over the electrically conductive layer, is formed tohave a smaller area than the electrically conductive layer so as toexpose an upper edge surface of the electrically conductive layer. 15.The semiconductor device according to claim 14, wherein the upper edgesurface exposed has the same width as the wiring layer.
 16. Thesemiconductor device according to claim 9, wherein the height from asurface of a base member constituting the circuit substrate to a surfaceof the resin layer is lower than the height of solder resist disposed ata perimeter portion of the area.
 17. The semiconductor device accordingto claim 9, wherein the electrically conductive layer has a groundpotential.